A Minimal Flavor Violating 2HDM at the LHC

TL;DR

This paper investigates a minimal flavor violating two Higgs doublet model, analyzing its implications for Higgs phenomenology at the LHC, including potential enhancements in decay rates and prospects for heavy Higgs detection.

Contribution

It introduces a novel 2HDM framework based on minimal flavor violation and performs global fits to current data, revealing significant effects on Higgs decay rates and heavy Higgs phenomenology.

Findings

Enhanced h --> gamma gamma rate in VBF and inclusive production

Milder constraints on light charged Higgs compared to other 2HDMs

Suppressed h --> tau+tau- rate possible independently

Abstract

We explore the phenomenology of a two Higgs doublet model where both Higgs doublets couple to up-type and down-type fermions with couplings determined by the minimal flavor violation ansatz. This 2HDM "Type MFV" generalizes 2HDM Types I-IV, where the decay rates of h --> bb and h --> tau+tau- are governed by MFV couplings independent of the Higgs couplings to gauge bosons or the top quark. To determine the implications of the present Higgs data on the model, we have performed global fits to all relevant data. Several surprisingly large effects on the light Higgs phenomenology can arise: (1) The modified couplings of the Higgs to fermions can enhance the h --> gamma gamma rate significantly in both VBF production (up to a factor of 3 or more) and the inclusive rate (up to a factor of 1.5 or more). (2) In the 2HDM Type MFV, the constraints on a light charged Higgs are milder than in 2HDM Types I-IV. Thus, there can be substantial charged Higgs loop contribution to the di-photon rate, allowing further enhancements of the di-photon rates. (3) The h --> tau+tau- rate can be (highly) suppressed, independently of the other decay channels. Furthermore, we studied the correlation between the light Higgs and the heavy Higgs phenomenology. We showed that even small deviations from the decoupling limit would imply good prospects for the detection of the heavy Higgs boson. In some regions of parameter space, a substantial range of M_H is already either ruled out or on the edge of detection. Finally we investigated the possibility that the heavy Higgs is close in mass to the light Higgs, providing additional h/H --> bb rate, as well as confounding the extraction of properties of the Higgs bosons.